Ring-style terminal block and submersible pump with ring-style terminal block

ABSTRACT

Embodiments of the invention provide an electrically-powered submersible pump. The pump has a pump housing, a ring-style terminal block including an annular component having a plurality of terminals, a motor contained within the pump housing, and a power source in communication with at least one of the plurality of terminals. Each of the plurality of terminals is spaced apart about the annular component and at least one terminal of the plurality of terminals extends outwardly from the annular component. The motor in communication with at least one of the plurality of terminals.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a division of U.S. patent application Ser. No.16/051,104, filed on Jul. 31, 2018, which claims priority to U.S.Provisional Patent Application No. 62/539,385, filed on Jul. 31, 2017,entitled “Ring-Style Terminal Block and Submersible Pump with Ring-StyleTerminal Block,” the entire contents of which are incorporated herein byreference.

BACKGROUND

Electric motors (e.g., induction and synchronous motors) typicallyinclude a stator and a rotor. The stator is mounted inside a housing andthe rotor is received within the stator. The stator is connected to apower source, which can provide an alternating current to the stator toproduce electromagnetic fields that drive rotation of the rotor relativeto the stator.

In many stator designs (and electrical machine designs, generally)multiple electrical wires must be connected to a power source. Sensors,if present in the system, may need to be connected to control wires thatcommunicate with equipment external from the electric machine. In orderto make the necessary connections to external cables and decreasemanufacturing complications, terminal boards have been used.

Terminal boards provide a series of electrically-conducting terminalsthat can receive multiple individual wires at a common terminal. Whenmultiple wires are coupled to a common, electrically-conductingterminal, the wires are in electrical communication with one another.Terminal boards of this type have reduced the complexity and labor costsassociated with installing and assembling electrical machines, aselectrical connections between multiple wires can be created withoutplacing each individual electrical wire in direct physical contact withanother electrical wire.

Terminal boards have also been used to create electrical connections tomotor stators. Simultaneously, the terminal board can act as a seal tothe motor cavity. Wires leading from the stator and other equipmentwithin the motor cavity are coupled to terminals extending from theterminal board inward toward the motor cavity. The exterior power sourcecan be connected to common terminals that extend outward from theterminal board away from the motor cavity, which places the stator inelectrical communication with the power source while sealing the motorcavity.

Traditionally, vertical terminal boards have been used to connect wiresto the terminal boards. Electrical wires running vertically (e.g.,parallel to the direction of the terminals) toward the terminals on avertical terminal board must be bent in order to make adequateconnections with the terminals. Bending wires increases the likelihoodthat a bad connection will be made, which can negatively impactoperation of the electric machine. The vertical terminal boards alsomake electrical machines more difficult to assemble and disassemble,which can increase maintenance and labor costs.

SUMMARY OF THE INVENTION

Embodiments of the invention provide a terminal board that improves thereliability of electrical connections made between a motor stator and apower source, while simultaneously eliminating many of the difficultiesassociated with installing, maintaining, and troubleshooting traditionalterminal boards with vertical terminals.

Some embodiments of the invention provide an electrically-poweredsubmersible pump. The pump has a pump housing, a ring-style terminalblock including an annular component having a plurality of terminals, amotor contained within the pump housing, and a power source incommunication with at least one of the plurality of terminals. Each ofthe plurality of terminals is spaced apart about the annular componentand at least one terminal of the plurality of terminals extendsoutwardly from the annular component. The motor in communication with atleast one of the plurality of terminals.

Some embodiments of the invention provide an electrically-poweredsubmersible pump. The pump has a pump housing, a motor contained withinthe pump housing, and a ring-style terminal block. The ring-styleterminal block includes an annular component having a plurality ofterminals, a top surface, a bottom surface opposite the top surface, andat least one mounting feature. Each one of the plurality of terminals isspaced apart circumferentially and at least one terminal of theplurality of terminals extends outwardly from the annular component. Themounting feature includes a cylindrical through hole extending from thetop surface of the annular component through the bottom surface of theannular component.

Some embodiments of the invention provide a submersible pump including apump housing defined by a motor housing and a terminal housing, a powercable, and a ring-style terminal block including an annular componenthaving a plurality of terminals. At least part of the power cableextends substantially vertically through the terminal housing. Thering-style terminal block is coupled to the motor housing such that theplurality of terminals extend outwardly from the annular componentsubstantially perpendicularly to the at least part of the power cableextending substantially vertically through the terminal housing.

These and other features of the invention will become more apparent fromthe following description of the illustrative embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front elevational assembly view depicting a ring-styleterminal block within a submersible pump, according to embodiments ofthe invention.

FIG. 2 is a top isometric view of an exemplary ring-style terminal blockfor use in the submersible pump of FIG. 1.

FIG. 3A is top plan view of the ring-style terminal block of FIG. 2.

FIG. 3B is a bottom plan view of the ring-style terminal block of FIG.2.

FIG. 3C is a cross-sectional view of the ring-style terminal block ofFIG. 2, where the cross-section is taken generally along the lines 3C-3Cin FIG. 3A.

FIG. 3D is a detailed view of the ring-style terminal block of FIG. 2,taken from the circle labeled FIG. 3D in FIG. 3A.

FIG. 4 is a top isometric view of the ring-style terminal block of FIG.2 installed within the submersible pump of FIG. 1.

FIG. 5 is a top plan view of the ring-style terminal block of FIG. 2installed within the submersible pump of FIG. 1.

FIG. 6 is a top isometric view of the ring-style terminal block of FIG.2 located within the submersible pump of FIG. 1, with a pump terminalhousing removed.

FIG. 7 is a top isometric view of the ring-style terminal block of FIG.2 having ring tongue connections formed between wires and the terminalson the ring-style terminal block.

FIG. 8 is a partial cross-sectional view of an assembled submersiblepump having the ring-style terminal block of FIG. 2 installed within thepump terminal housing.

FIG. 9 is a front, top isometric view of a sealed submersible pumphaving a lifting feature used during a pump assembly process.

FIG. 10 is a process diagram detailing a method of installing aring-style terminal block within a submersible pump according toembodiments of the invention.

Corresponding reference characters indicate corresponding partsthroughout the several views. Although the drawings representembodiments of the invention, the drawings are not necessarily to scaleand certain features may be exaggerated in order to better illustrateand explain the embodiments of the invention.

DETAILED DESCRIPTION

Before any embodiments of the invention are explained in detail, it isto be understood that the invention is not limited in its application tothe details of construction and the arrangement of components set forthin the following description or illustrated in the following drawings.The invention is capable of other embodiments and of being practiced orof being carried out in various ways. Also, it is to be understood thatthe phraseology and terminology used herein is for the purpose ofdescription and should not be regarded as limiting. The use of“including,” “comprising,” or “having” and variations thereof herein ismeant to encompass the items listed thereafter and equivalents thereofas well as additional items. Unless specified or limited otherwise, theterms “mounted,” “connected,” “supported,” and “coupled” and variationsthereof are used broadly and encompass both direct and indirectmountings, connections, supports, and couplings. Further, “connected”and “coupled” are not restricted to physical or mechanical connectionsor couplings.

The following discussion is presented to enable a person skilled in theart to make and use embodiments of the invention. Various modificationsto the illustrated embodiments will be readily apparent to those skilledin the art, and the generic principles herein can be applied to otherembodiments and applications without departing from embodiments of theinvention. Thus, embodiments of the invention are not intended to belimited to embodiments shown, but are to be accorded the widest scopeconsistent with the principles and features disclosed herein. Thefollowing detailed description is to be read with reference to thefigures, in which like elements in different figures have like referencenumerals. The figures, which are not necessarily to scale, depictselected embodiments and are not intended to limit the scope ofembodiments of the invention. Skilled artisans will recognize theexamples provided herein have many useful alternatives and fall withinthe scope of embodiments of the invention.

FIG. 1 illustrates a partially assembled submersible pump 100. Thesubmersible pump 100 includes a pump housing 101, which is defined by amotor housing 102 and a terminal housing 104. A ring-style terminalblock 20 is installed within the pump housing 101 to create electricalcommunication between electrical components (not shown) contained withinthe motor housing 102 and power cables 106 and control cables (108,shown in FIG. 6) contained within the terminal housing 104. The powercables 106 and control cables 108 extend from the terminal block 20through the terminal housing 104 and lead away from the submersible pump100. The power cables 106 and control cables 108 can be connected toexterior electrical components (e.g., sensors) or power sources (e.g., a110 Volt, 230 Volt, or 460 Volt AC power source), for example.

FIGS. 2-3D illustrate details of the terminal block 20. The terminalblock 20 has an annular component 22 that supports terminals 32, whichare spaced apart circumferentially about the annular component 22. Theannular component 22 has a radially inward facing surface 24 at leastpartially defined by a radius R1 and a radially outward facing surface26 at least partially defined by a radius R2 larger than and concentricwith the radius R1, as shown in FIG. 3B. The annular component 22 isfurther defined by a top surface 28 extending between the radiallyinward facing surface 24 and the radially outward facing surface 26, aswell as a bottom surface 30 extending between the radially inward facingsurface 24 and the radially outward facing surface 26, opposite the topsurface 28. The radially inward facing surface 24, the radially outwardfacing surface 26, the top surface 28, and the bottom surface 30collectively define the exterior shape of the annular component 22. Thedistance between the top and bottom surfaces 28, 30 defines a thickness29 of the annular component 22. The thickness 29 may range between about5 millimeters and about 100 millimeters, for example. In one embodiment,the thickness 29 is about 30 millimeters. A radial depth of the annularcomponent 22 is defined by the difference between the radius R2 and theradius R1, as illustrated in FIGS. 3B and 3C. As an example, the radiusR1 could be between about 40 millimeters and about 200 millimeters,while the radius R2 could be between about 45 millimeters and about 300millimeters.

Several terminals 32 are formed integrally within the annular component22. In some examples, the annular component 22 is molded around bronzealloy terminals 32, which extend both inwardly and outwardly from theannular component 22. Alternatively, the terminals 32 can be threadedinto the annular component 22 once the annular component 22 has beenmolded. The annular component 22 can be formed of a semi-crystalline,insulating material, such as polyester, polybutylene terephthalate, orpolyethylene terephthalate, for example. In some applications, a VALOX™material is used to form the annular component 22. The terminals 32 canbe spaced apart circumferentially about the annular component 22. Eachterminal 32 can be evenly spaced circumferentially about the annularcomponent 22. The spacing between each terminal 32 may vary, however,based upon the intended use for the terminals 32, the electrical machinethat the ring-style terminal block is being installed into, or otherdesign factors.

One or more of the terminals 32 extends radially away from the annularcomponent 22. As shown in FIG. 2, several terminals 32 extend radiallyinward from the radially inward facing surface 24 of the annularcomponent 22. Similarly, several terminals 32 extend radially outwardfrom the radially outward facing surface 26 of the annular component 22.In some embodiments, one group of terminals 32 extends radially inwardfrom the radially inward facing surface 24 of the annular component 22and a second group of terminals 32 extends radially outward from theradially outward facing surface 26 of the annular component 22. In stillother examples, each of the terminals 32 in the first and second groupsextend entirely through the annular component 22 and both radiallyinward from the radially inward facing surface 24 and radially outwardfrom the radially outward facing surface 26 of the annular component 22.

A variety of different terminal styles can be used in the terminal block20. As illustrated, each of the terminals 32 are threaded screwterminals. As shown in FIG. 7, each of the terminals 32 may have ashoulder 72 that extends radially outward from the terminal 32 to form aflat mounting surface for receiving and securing lugs, nuts, or otherwire coupling features. In some examples, two or more distinct types orsizes of terminals 32 are present in the terminal block 20. For example,a terminal block 20 may include both power cable terminals 48 andcontrol cable terminals 50. In some embodiments, the power cableterminals 48 are larger and can accept larger electrical connectionsthan the control cable terminals 50. For example, the power cableterminals 48 can accept electrical connections between 2-gauge and12-gauge, while the control cable terminals 50 support electricalconnections between 14-gauge and 18-gauge. Additionally, the power cableterminals 48 can receive and support power cable nuts 52, which cansecure electrical connections on the power cable terminals 48, as shownin FIG. 7. Likewise, the control cable terminals 50 can support controlcable nuts (not shown). In some embodiments, the power cable nuts 52 andcontrol cable nuts are hex nuts that have interior threads that engagethe threaded power cable terminals 48 and control cable terminals 50that they correspond to. In one example, the power cable nuts 52 have a⅜″ thread size, while the control cable nuts have a #10 thread size. Inan alternative embodiment, each of the terminals 32 is a threaded holeformed of electrically conducting material. In these examples, wiresextending away from the motor stator and the power source can be coupledto screws that can be threaded into the terminals 32, which then placesthe wires in electrical communication with one another.

The number and types of terminals 32 in the terminal block 20 can betailored to individual electrical machine requirements. In oneembodiment, the terminal block 20 includes twenty-two total terminals32, with twelve power cable terminals 48 and ten control cable terminals50 each extending entirely through the annular component 22. Fordifferent machines or different machine sizes, the terminal block 20could include nine power cable terminals 48, or any other number ofpower cable or control cable terminals 48, as needed.

Some terminal rings 20 include locating features 46. The locatingfeatures 46 can be spaced apart the top surface 28 (or any othersuitable surface) of the annular component 22, and may include lettersand/or numbers that are molded into the annular component 22. Thelocating features 46 could be slightly raised from or slightly embeddedinto the top surface 28 of the annular component 22 to help identifyeach terminal 32 or to provide other relevant information about theterminal block 20. In some embodiments, both the top surface 28 and thebottom surface 30 include letters or numbers that provide installationinstructions or other identifying information. For example, locatingfeatures 46 in the form of text on the top surface 28 may provideinstructions on how to install and wire the terminal block 20 to a 230 Vsource, while text-based locating features 46 on the bottom surface 30may provide instructions on how to install and wire the terminal block20 to a 460 V source. The locating features 46 can also include otherindicia, including shapes, colors, or combinations of any of these, suchas the letter and number combination shown. The locating features 46 canbe imparted onto the annular component 22 in a number of ways, includingdrawing, printing, molding, casting, carving, or painting, for example.The locating features 46 can promote easier installation of the terminalblock 20 by providing visible notice to the installer of the terminalblock 20 and help ensure that proper electrical connections are made atthe proper terminals 32. The physical shape and height of the locatingfeatures 46 can also be of assistance when the terminal block 20 islocated in a position that is difficult to see. Instead of reading, auser can simply feel the locating features 46 to determine a correctconnection location for a cable. The locating features 46 can also becolor-coded so that the color present on the terminal block 20corresponds to a color of wire that should be placed in communicationwith a particular terminal 32, which can further simplify theinstallation process.

The annular component 22 can include barriers 34, 36 spaced about theannular component 22 to separate the terminals 32. In some embodiments,the radially inward facing surface 24 of the annular component 22includes a first circumferential array of barriers 34 that each extendradially inward from the radially inward facing surface 24 of theannular component 20. The barriers 34 separate each of the plurality ofterminals 32 that extend radially inward from the radially inward facingsurface 24. Accordingly, each terminal 32 extending inward from theradially inward facing surface 24 can have at least one barrier 34placed circumferentially between it and each adjacent terminal 32. Someof the terminals 32 can also be separated from each adjacent terminal 32by more than one barrier 34. Alternatively, barriers 34 can be omittedin certain locations along the annular component 22, and terminals 32may be separated by spacing alone. The barriers 34 can be spaced outevenly about the circumference of the radially inward facing surface 24or could be distributed otherwise to accommodate different electricalmachine requirements. For example, the spacing between barriers 34 couldbe varied to accommodate different terminal sizes, like the power cableterminals 48 and control cable terminals 50 discussed above.Accordingly, the barriers 34 separating power cable terminals 48 couldhave greater circumferential spacing than barriers 34 separating controlcable terminals 50.

The radially outward facing surface 26 of the annular component caninclude a second circumferential array of barriers 36. Each barrier inthe second circumferential array of barriers 36 extends radially outwardfrom the radially outward facing surface 26 of the annular component 22to separate each adjacent terminal 32 that extends radially outward fromthe radially outward facing surface 26. More than one barrier 36 can beextend between each set of terminals 32 or, alternatively, terminals 32may not be separated by barriers 36 at all. Similar to the firstcircumferential array of barriers 34, the second circumferential arrayof barriers 36 can be spaced differently to accommodate differentterminal 32 sizes. Each of the barriers 34 in the first plurality can beradially aligned with barriers 36 in the second plurality. Accordingly,each of the barriers 34, 36 then extend radially inward and radiallyoutward along a common radius, as shown in FIG. 3D. In some embodiments,the number of barriers 34 and barriers 36 is equal.

The barriers 34, 36 can extend from the bottom surface 30 of the annularcomponent 22 to the top surface 28 to have a barrier 34, 36 depthapproximately equal to the thickness 29 of the annular component 22.Each of the barriers 34, 36 can have sections that extend continuouslyoutward from and generally flush with both the top surface 28 and thebottom surface 30 of the annular component 22. Alternatively, each ofthe barriers 34, 36 can have a barrier depth 34, 36 that is larger thanthe thickness 29 of the annular component 22. Each barrier 34, 36 couldextend axially beyond one or both of the top surface 28 and the bottomsurface 30 of the annular component 22. In still other alternatives, thebarriers 34, 36 can have a barrier depth that is less than the thickness29 of the annular component 22. Accordingly, the barriers 34, 36 can beentirely axially contained between the top surface 28 and the bottomsurface 30 of the annular component 22.

In an alternative embodiment, the annular component 22 of the terminalblock 20 has two rows of molded terminals 32 stacked circumferentiallyaround the annular component 22. Each of the terminals 32 could extendradially outward or radially inward from the annular component 22, sothat all terminals extend outward from a common surface of the annularcomponent. The annular component 22 may include only one of radiallyinward facing barriers 34 or radially outward facing barriers 36, asterminals extend away from only one of the radially-inward facingsurface 24 and the radially-outward facing surface 26 of the annularcomponent 22.

The terminal block 20 can also include one or more mounting features 38.The mounting features 38 can help locate and secure the terminal block20 within an electrical machine, like the submersible pump 100 shown inFIG. 1. The mounting features 38 can include a cylindrical through hole40 that extends entirely through the annular component 22 from the topsurface 28 of the annular component through the bottom surface 30.Additionally, the mounting features 38 can each include cylindricalsteel (or other metallic materials, such as brass or aluminum, forexample) inserts 42 coupled to the cylindrical through holes 40 formedin the annular component 22. The cylindrical steel inserts 42 can bemolded integrally within the cylindrical through hole 40 or adhesivelyconnected to the cylindrical through-hole 40, for example. As shown inFIG. 2, the cylindrical steel insert 42 may extend beyond the bottomsurface 30 of the annular component 22, which can make the terminalblock 20 more readily locatable at a desired mounting position within anelectric machine. In some embodiments, the cylindrical steel insert 42extends beyond both the top surface 28 and the bottom surface 30 of theannular component 22. The mounting features 38 can further define afastener seat 44, which is located on the top surface 28 of the annularcomponent 22.

FIGS. 3A-3D illustrate the dimensional relationships between theterminals 32 and the barriers 34, 36 on the terminal block 20. In someexamples, the power cable terminals 48 can each be grouped together, sothat each power cable terminal 48 is circumferentially adjacent to atleast one other power cable terminal 48. The control cable terminals 50are also then grouped together, so that each control cable terminal 50is circumferentially adjacent to at least one other control cableterminal 50. Alternatively, the power cable terminals 48 and controlcable terminals 50 can alternate circumferentially about the terminalblock 20. The number of power cable terminals 48 and control cableterminals 50 formed within the annular component 22 may not always beequal, so many other terminal 48, 50 positioning patterns are possible.

FIGS. 3A and 3B illustrate example shapes and orientations of themounting features 38. The mounting features 38 may extend inwardly oroutwardly beyond the radially inward facing surface 24 or the radiallyoutward facing surface 26, respectively, and can be defined by radiithat differ from radii R1 and R2. For example, the mounting features 38can jut inwardly from the radially-inward facing surface 24 to a radiusR3, which is smaller than R1. The mounting features 38 can extendoutwardly from the radially outward facing surface 26 as well. Forexample, the mounting features 38 can extend outwardly to a radius R4,which is larger than the radius R2. The size difference between radiiR1, R2, R3 and R4 forms a fastener seat 44 (shown in FIG. 2). Thefastener seat 44 provides a large surface for which a fastener orcoupling device may engage and hold a terminal block 20 into placewithin an electric machine assembly. Although described as being definedby radii R3 and R4, the mounting features 38 may instead be defined bysubstantially planar walls. For example, the mounting features 38 can bedefined by inner and outer walls formed in planes extendingapproximately tangent to the circles defined by radii R3 and R4,respectively.

The mounting features 38 can be arranged on the terminal block 20 in avariety of orientations about the annular component 22. In someembodiments, three identically-sized mounting features 38 are spacedevenly about the circumference of the annular component 22. The number,size, and position of the mounting features 38 can be adjusted basedupon the mounting requirements of the electric machine the terminalblock 20 will be installed into.

The barriers 34, 36 can also be at least partially defined by a radius.In some embodiments, each of the barriers 34 extend radially inward to adistance R5 from the center of the annular component 22, which issmaller than and concentric with both radii R1 and R3. Each of thebarriers 34 can extend inwardly to the radius R5, for example.Similarly, each of the barriers 36 can extend radially outward from theradially outward facing surface 26 to a distance R6, which is largerthan both radii R2 and R4. In other examples, the radius R5 can belarger than or equal to the radius R3, while the radius R6 can besmaller than or equal to the radius R4. Each of the inward-extendingbarriers 34 can be uniformly shaped, while each of the outward-extendingbarriers 36 can also be uniformly shaped.

As shown in FIG. 3D, the barriers 34, 36 can have a generally tooth-likeshape. The tooth-like shape can be defined by a barrier base 60 and abarrier tip 62. The barrier base 60 can be wider than the barrier tip62, which gives the barriers 34, 36 an inward taper. Radii can partiallydefine the base 60 and barrier tips 62 to remove sharp corners from thebarriers 34, 36. The barrier 34, 36 spacing can be defined by angles αand β. In the illustrative embodiment, angle α is defined as the anglebetween the centerline of a barrier 36 and the centerline of an adjacentterminal 32. When the barriers 34 and 36 share a common centerline, asshown in FIG. 3D, both barriers 34, 36 are at least partially dependenton angle α. The angle α may vary in magnitude, and can be largelydependent upon the number and size of terminals 32 that are formedintegrally within the annular component 22. As illustrated, the angle αis between about 7° and about 9°.

The angle β is defined as the angle between the centerlines ofcircumferentially adjacent barriers 34, 36. The angle β can be abouttwice the magnitude of the angle α, so that the terminal 32 centerlineis approximately centered between adjacent barriers 34, 36. In terminalblocks 20 having at least two distinct sizes of terminal 32 (e.g., powercable terminals 48 and control cable terminals 50), a second set ofangles α′ and β′ can be used to separate control cable terminals 50, asshown in FIG. 3B. If the angles α′ and β′ differ from the angles αand β,the angular spacing between barriers 34, 36 is not constant throughoutthe annular component 22. The second set of angles α′ and β′ may besmaller than the first set of angles α and β, so that thecircumferential spacing of barriers 34, 36 is less between control cableterminals 50 than it is between power cable terminals 48. This providesthe larger power cable terminals 48 with a larger space around them, sothat the barriers 34, 36 will not overly restrict the type of terminalconnection that can be made at the power cable terminals 48.

FIGS. 4-10 illustrate a process 200 for assembling the terminal block 20into a submersible pump 100. As shown in FIGS. 4-5, the terminal block20 can be first positioned within the motor housing 102, on top of abearing plate 105. Counterbored holes can be formed in the bearing plate105 to receive the cylindrical steel inserts 42 of the mounting features38 or other anchoring mechanisms. The cylindrical steel inserts 42extend into the counterbored holes, which locate and secure the terminalblock 20 in a proper radial orientation relative to the motor housing102. In some embodiments, the terminal block 20 is aligned substantiallyconcentrically with a cylindrical outer surface of the pump housing 102.Once the terminal block 20 is positioned within the motor housing 102,anchors 56 (shown in FIG. 6) can been placed through the cylindricalsteel inserts 42 (or through the through holes 40, if the cylindricalsteel inserts 42 are omitted) and tightened within the threadedcounterbored holes in the bearing plate 105 to prevent axial and radialmovement of the terminal block 20. The anchors 56 can be tightened toengage the fastener seats 44 formed on the mounting features 38.

Once the terminal block is secured to the motor housing 102, electricalconnections between the motor, sensors, and the power source can becreated. The bearing plate 105 has designated openings 107 to allowelectrical cables contained within the motor housing 102 to extendupward to the terminal block 20, where electrical connections can bemade. The terminal housing 104 (which is removed for clarity in FIG. 6)is suspended above the terminal ring 20 at step 202. Electrical powersource cables 106 and control connections 108 then extend verticallytoward the terminal block, where they can be connected to terminals 32in the terminal block 20.

Electrical connections are made on the terminal block 20 at step 204. Asshown in FIG. 7, wires extending from the motor stator 70 can first beplaced in electrical communication with a pump connection 66. In someexamples, the pump connection 66 is a ring tongue connector formed of anelectrically conducting material and having a through-hole sized toreceive a threaded screw terminal 32. If sized properly, the pumpconnection 66 will provide at least some electrical contact between theterminal 32 and the pump connection 66, so that the wire extending fromthe motor stator 70 is placed in electrical communication with theterminal 32. A power cable nut 52 can then be threaded onto the terminal32 and tightened to engage the power cable nut 52, the pump connection66, and the shoulder 72 together. To speed up the installation process,a torque wrench can be used to tighten the power cable nuts 52.Following the same general process, the power connection 64 can beplaced into electrical contact with the terminal 32, again using a powercable nut 52. The same general process can then be used to couple wireconnections on the control cables to the terminal ring 20 using controlcable nuts. The annular component 22, terminals 32, and wire connections64, 66 are formed of materials having similar expansion coefficients toavoid loosening between metals and issues with poor contact resistance.As illustrated in FIG. 7, electrical connections coming from the motorhousing 102 can be positioned on the portion of the terminal 32extending radially inward from the radially inward facing surface 24annular component 22, while connections to exterior control units, aswell as power sources are positioned on the portion of the terminal 32extending radially outward from the radially outward facing surface 26of the annular component 22. Alternatively, multiple wire connections64, 66 can be received on the same end of a terminal 32. For example,embodiments of the terminal ring 20 having terminals 32 extending onlyradially inward from the radially inward facing surface 24 (oralternatively, only radially outward from the radially outward facingsurface 26) can receive both of the connections 64, 66 on the same endof the terminal 32, and can each be engaged by a common power cable nut52 or control cable nut.

Once the wire connections 64, 66 have been coupled to the terminals 32,the terminal housing 104 can be lowered over the motor housing 102 atstep 206, as shown in FIG. 8. Once the terminal housing 104 is loweredover the terminal block 20, the terminal block 20 is entirely containedwithin the pump housing 101. With the electrical connections made ateach of the terminals 32, the electrical power source cables 106 can beplaced in electrical communication with the power source to drive thepump 100. The pump 100 includes a shaft 112 and an impeller (not shown)coupled to the shaft 100 and used to displace fluid. The terminalhousing 104 and the motor housing 102 are then coupled together (e.g.,using fasteners) to form a seal at step 208, so that the stator 110 andterminal block 20 remain substantially dry during pump operation.

Once the motor housing 102 and terminal housing 104 are sealinglycoupled together, any material handling equipment used during assemblycan be removed. As shown in FIG. 9, a lifting device 120 with a cableretaining bracket 122 can be directly coupled to the terminal housing104. The lifting device 120 is typically used to raise the terminalhousing 104 above the motor housing 102 during the wire connection step204. To properly connect the electrical power source cables 106 andcontrol connections 108 to the terminals 32 of the terminal block 20,the terminal housing 104 is suspended over the terminal block 20 usingan overhead lift in connection with the lifting device 120. An installercan make the necessary electrical connections to the terminal block 20,lower the terminal housing 104 onto the motor housing 102, and thenremove the lifting device 120 (e.g., by removing the fasteners 124 fromthe terminal housing).

It will be appreciated by those skilled in the art that while theinvention has been described above in connection with particularembodiments and examples, the invention is not necessarily so limited,and that numerous other embodiments, examples, uses, modifications anddepartures from the embodiments, examples, and uses are intended to beencompassed by the claims attached hereto. Various features andadvantages of the invention are set forth in the following claims.

1. An electrically-powered submersible pump, the pump comprising: a pumphousing; a ring-style terminal block including an annular componenthaving a plurality of terminals, each of the plurality of terminalsbeing spaced apart about the annular component, at least one terminal ofthe plurality of terminals extending outwardly from the annularcomponent; a motor contained within the pump housing, the motor incommunication with at least one of the plurality of terminals; and apower source in communication with at least one of the plurality ofterminals.
 2. The pump of claim 1, wherein the pump housing includes aterminal housing and a motor housing, the terminal housing and the motorhousing coupled together to form a seal around the ring-style terminalblock and a stator of the motor.
 3. The pump of claim 2, wherein thering-style terminal block is secured to the motor housing via one ormore anchors.
 4. The pump of claim 1, wherein the plurality of terminalsincludes at least two distinct sizes of terminals, one sizecorresponding to a power cable in communication with the power source.5. The pump of claim 1, wherein the annular component includes aradially inward facing surface and a radially outward facing surface,the radially inward facing surface is at least partially defined by afirst radius and the radially outward facing surface at least partiallydefined by a second radius larger than the first radius.
 6. The pump ofclaim 5, wherein annular component further includes a top surfaceextending between the radially inward facing surface and the radiallyoutward facing surface, and a bottom surface extending between theradially inward facing surface and the radially outward facing surfaceand formed opposite the top surface, the bottom surface separated fromthe top surface by a thickness.
 7. The pump of claim 5, wherein at leastone terminal of the plurality of terminals extends radially inward fromthe radially inward facing surface of the annular component and at leastone terminal of the plurality of terminals extends radially outward fromthe radially outward facing surface of the annular component.
 8. Thepump of claim 5, wherein the plurality of terminals extend radiallyinward from the radially inward facing surface, through the annularcomponent, and radially outward from the radially outward facingsurface.
 9. The pump of claim 5, wherein the radially inward facingsurface of the annular component comprises a first circumferential arrayof barriers extending radially inward from the radially inward facingsurface of the annular component to separate each of the plurality ofterminals from adjacent terminals.
 10. The pump of claim 9, wherein theradially outward facing surface of the annular component comprises asecond circumferential array of barriers extending radially outward fromthe radially outward facing surface of the annular component to separateeach of the plurality of terminals from adjacent terminals.
 11. The pumpof claim 9, wherein each of the first circumferential array of barriersis uniformly shaped.
 12. The pump of claim 9, wherein each barrier ofthe first circumferential array of barriers is axially contained betweenthe top surface and the bottom surface.
 13. The pump of claim 10,wherein each barrier of the second circumferential array of barriers isaxially contained between the top surface and the bottom surface.
 14. Anelectrically-powered submersible pump, the pump comprising: a pumphousing; a motor contained within the pump housing; and a ring-styleterminal block including: an annular component including a plurality ofterminals, each one of the plurality of terminals being spaced apartcircumferentially, at least one terminal of the plurality of terminalsextending outwardly from the annular component, a top surface, a bottomsurface opposite the top surface, and at least one mounting featureincluding a cylindrical through hole extending from the top surface ofthe annular component through the bottom surface of the annularcomponent.
 15. The pump of claim 14, wherein each of the mountingfeatures further includes a cylindrical insert that extends at leastpartially into the cylindrical through hole, the motor includes a motorhousing with a bearing plate, and an anchor extends through eachcylindrical insert to secure the ring-style terminal block to thebearing plate.
 16. A submersible pump comprising: a pump housing definedby a motor housing and a terminal housing; a power cable, at least partof the power cable extending substantially vertically through theterminal housing; and a ring-style terminal block including an annularcomponent having a plurality of terminals, the ring-style terminal blockcoupled to the motor housing such that the plurality of terminals extendoutwardly from the annular component substantially perpendicularly tothe at least part of the power cable extending substantially verticallythrough the terminal housing.
 17. The submersible pump of claim 16,wherein the motor housing includes a bearing plate with openings, thesubmersible pump including a motor cable configured to extend throughthe bearing plate openings to the ring-style terminal block.
 18. Thesubmersible pump of claim 16, wherein a control cable extendssubstantially vertically through the terminal housing.
 19. Thesubmersible pump of claim 16, wherein each of the power cable, a motorcable, and a control cable are in electrical communication with at leastone of the plurality of terminals.
 20. The submersible pump of claim 16wherein at least one terminal of the plurality of terminals extendsradially inward from a radially inward facing surface of the annularcomponent and at least one terminal of the plurality of terminalsextends radially outward from a radially outward facing surface of theannular component, wherein the power cable is electrically coupled to atleast one of the plurality of terminals extending from one of theradially inward facing surface or the radially outward facing surface,and a motor cable is electrically coupled to at least one of theplurality of terminals extending from the other of the radially inwardfacing surface or the radially outward facing surface.